Landei has the right answer, I think, but it's not unpacked very thoroughly. Let's start at the end:
scala> Console println 2 * _
<console>:8: error: missing parameter type for expanded function
((x$1) => Console.println(2.$times(x$1)))
Console println 2 * _
^
Okay, so we see that on its own, Console println 2 * _
is trying to create a function via explicit eta expansion, except it doesn't know the return parameter type so it can't.
Now let's try a code block that returns a function.
scala> { println("Hi"); (i: Int) => i*5 }
Hi
res1: Int => Int = <function1>
So, as with everything, you execute the entire block (including side-effecting statements like println
), and return the return value which is your function.
Now, as Landei said, placeholder syntax only works for one argument in one (simple) expression, and in the second case we don't have a simple expression but a block expression (consisting of two simple expressions). So we're not using placeholder syntax, we're creating a function. And we do it in a code block:
is foreach { println("Hi.") ; Console println 2 * _ }
which, since we don't start with function arguments, is interpreted as a plain parameter, except we can in almost any context--argument lists included--replace a simple expression (x)
with a block expression { stuff; x }
. So we can think of it as
is foreach ({ println("Hi.") ; Console.println 2 * _ })
Now the type inferencer knows what the return type is supposed to be, so it runs that code block which prints out "Hi" and creates a function, then passes that function (just once, at the beginning!) to foreach
. If the type inferencer could look across lines to figure out types, it would be equivalent to this:
val temp = { println("Hi."); Console.println 2 * _ }
is foreach (temp)